Crates.io | calc_rational |
lib.rs | calc_rational |
version | 2.0.0 |
source | src |
created_at | 2023-04-14 04:37:31.332126 |
updated_at | 2024-09-07 00:04:04.340391 |
description | CLI calculator for rational numbers. |
homepage | |
repository | https://git.philomathiclife.com/repos/calc_rational/ |
max_upload_size | |
id | 838924 |
size | 178,166 |
calc_rational
calc_rational
consists of a binary crate calc
and a library crate
calc_lib
. calc
is a CLI calculator for basic
rational number arithmetic using standard operator precedence and associativity. Internally, it is
based on Ratio<T>
and BigInt
.
[zack@laptop ~]$ calc
2.71828^0^3.14159 + -1!
> 0
s
> 0
@^0
> 1
s
> 1
@/3 * 3
> 1
s
> 1
|@2 - 9|^(1 - 2*3)
> 1/32768
s
> 1/32768
> 0.000030517578125
round(@, 3)
> 0
round(@, 6)
> 31/1000000
> 0.000031
2/3
> 2/3
> 0.666666667
rand()
> 939435294927814822
rand(1+9,10!)
> 2660936
1+4 mod 2 + 1
> 2
-5 mod 2
> 1
-5 mod -2
> 1
5 mod -2
> 1
9^0.5
> 3
(4/9)^(-1/2)
> 3/2
q
[zack@laptop ~]$
The following are the list of expressions in descending order of precedence:
@
, ()
, ||
, round()
, rand()
!
^
-
(unary negation operator)*
, /
, mod
+
, -
All binary operators are left-associative sans ^
which is right-associative.
Any expression is allowed to be enclosed in ()
. Note that parentheses are purely for grouping expressions;
in particular, you cannot use them to represent multiplication (e.g., 4(2)
is grammatically incorrect and
will result in an error message).
Any expression is allowed to be enclosed in ||
. This unary operator represents absolute value.
!
is the factorial operator. Due to its high precedence, something like -i!^j! for i, j ∈ ℕ is
the same thing as -((i!)^(j!)). If the expression preceding it does not evaluate to a non-negative integer,
then an error will be displayed. Spaces and tabs are not ignored; so 1 !
is grammatically incorrect and
will result in an error message.
^
is the exponentiation operator. The expression left of the operator can evaluate to any rational number;
however the expression right of the operator must evaluate to an integer or ±1/2 unless the expression on
the left evaluates to 0
or 1
. In the event of the former, the expression right of the operator must evaluate
to a non-negative rational number. In the event of the latter, the expression right of the operator can evaluate to
any rational number. Note that 0^0
is defined to be 1. When the operand right of ^
evaluates to ±1/2, then
the left operand must be the square of a rational number.
The unary operator -
represents negation.
The operators *
and /
represent multiplication and division respectively. Expressions right of /
must evaluate to any non-zero rational number; otherwise an error will be displayed.
The binary operator mod
represents modulo such that n mod m = r = n - m*q for n,q ∈ ℤ, m ∈ ℤ\{0}, and r ∈ ℕ
where r is the minimum non-negative solution.
The binary operators +
and -
represent addition and subtraction respectively.
With the aforementioned exception of !
, all spaces and tabs before and after operators are ignored.
round(expression, digit)
rounds expression
to digit
-number of fractional digits. An error will
be displayed if called incorrectly.
rand(expression, expression)
generates a random 64-bit integer inclusively between the passed expressions.
An error will be displayed if called incorrectly. rand()
generates a random 64-bit integer.
A number literal is a non-empty sequence of digits or a non-empty sequence of digits immediately followed by .
which is immediately followed by a non-empty sequence of digits (e.g., 134.901
). This means that number
literals represent precisely all rational numbers that are equivalent to a ratio of a non-negative integer to
a positive integer whose sole prime factors are 2 or 5. To represent all other rational numbers, the unary
operator -
and binary operator /
must be used.
The empty expression (i.e., expression that at most only consists of spaces and tabs) will return the result from the previous non-(empty/store) expression in decimal form using the minimum number of digits. In the event an infinite number of digits is required, it will be rounded to 9 fractional digits using normal rounding rules first.
To store the result of the previous non-(empty/store) expression, one simply passes s
. In addition to storing the
result which will subsequently be available via @
, it displays the result. At most 8 results can be stored at once;
at which point, results that are stored overwrite the oldest result.
@
is used to recall previously stored results. It can be followed by any digit from 1
to 8
.
If such a digit does not immediately follow it, then it will be interpreted as if there were a 1
.
@i
returns the i-th most-previous stored result where i ∈ {1, 2, 3, 4, 5, 6, 7, 8}.
Note that spaces and tabs are not ignored so @ 2
is grammatically incorrect and will result in an error message.
As emphasized, it does not work on expressions; so both @@
and @(1)
are grammatically incorrect.
All inputs must only contain the ASCII encoding of the following Unicode scalar values: 0
-9
, .
, +
, -
,
*
, /
, ^
, !
, mod
, |
, (
, )
, round
, rand
, ,
, @
, s
, <space>, <tab>,
<line feed>, <carriage return>, and q
. Any other byte sequences are grammatically incorrect and will
lead to an error message.
Errors due to a language violation (e.g., dividing by 0
) manifest into an error message. panic!
s
and io::Error
s caused by writing to the global
standard output stream lead to program abortion. On OpenBSD-stable when compiled with the priv_sep
feature,
it will error if pledge(2)
errors with the promise of "stdio"
.
q
with any number of spaces and tabs before and after or sending EOF
will cause the program to terminate.
Licensed under either of
at your option.
Unless you explicitly state otherwise, any contribution intentionally submitted inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.
This package will be actively maintained until it is deemed “feature complete”. There are really only two properties that will always be true. First, the grammar that generates a “reasonable” superset of the language will be an unambiguous context-free grammar with expression precedence and binary operator associativity embedded within. Last, the language will only deal with the field of rational numbers.
The crate is only tested on x86_64-unknown-linux-gnu
and x86_64-unknown-openbsd
targets, but it should work
on most platforms.
For a more precise specification of the “calc language”, one can read the calc language specification.